In the last two decades, remarkable progress has been made in understanding stars. This graduate-level textbook provides a systematic, self-contained and lucid introduction to the physical processes and fundamental equations underlying all aspects of stellar astrophysics. This timely volume provides authoritative astronomical discussions as well as rigorous mathematical derivations and illuminating explanations of the physical concepts involved. In addition to traditional topics such as stellar interiors and atmospheres, the reader is introduced to stellar winds, mass accretion, nuclear astrophysics, weak interactions, novae, supernovae, pulsars, neutron stars and black holes. A concise introduction to general relativity is also included. At the end of each chapter, exercises - more than 100 in all - and helpful hints are provided to test and develop the understanding of the student. As the first advanced textbook on stellar astrophysics for nearly three decades, this long-awaited volume provides a thorough introduction for graduate students and an up-to-date review for researchers.
Advanced Stellar Astrophysics
Advanced Stellar Astrophysics University of Maryland College Park CAMBRIDGE UNIVERSITY PRESS
cambridge university press Cambridge, New York, Melbourne, Madrid, Cape Town, Singapore, São Paulo, Delhi, Tokyo, Mexico City Cambridge University Press The Edinburgh Building, Cambridge CB2 8RU, UK Published in the United States of America by Cambridge University Press, New York Information on this title: /9780521581882 Cambridge University Press 1998 This publication is in copyright. Subject to statutory exception and to the provisions of relevant collective licensing agreements, no reproduction of any part may take place without the written permission of Cambridge University Press. First published 1998 A catalogue record for this publication is available from the British Library Library of Congress Cataloguing in Publication data Rose, William K. (William Kenneth), 1935 Stellar astrophysics/. p. cm. Includes bibliographical references and index. ISBN 0 521 58188 5. ISBN 0 521 58833 2 (pbk.) 1. Stars. 2. Astrophysics. I. Title. QB801.R57 1998 523.8 dc21 97 11052 CIP isbn 978-0-521-58188-2 Hardback isbn 978-0-521-58833-1 Paperback Cambridge University Press has no responsibility for the persistence or accuracy of URLs for external or third party internet websites referred to in this publication, and does not guarantee that any content on such websites is, or will remain, accurate or appropriate. Information regarding prices, travel timetables, and other factual information given in this work is correct at the time of first printing but Cambridge University Press does not guarantee the accuracy of such information thereafter.
Contents Preface xiii 1 Star formation and stellar evolution: an overview 1 1.1 A short history of stellar astrophysics 1 1.2 The Hertzsprung-Russell (H-R) diagram 3 1.3 Spectroscopic binary stars 8 1.4 Star formation 75 1.5 Stellar evolution 19 1.6 Star-forming regions and very low-mass stars 27 2 Introduction to the physics of stellar interiors and the equations of stellar structure 36 2.1 The equation of state and the first law of thermodynamics 36 2.2 Hydrostatic equilibrium 38 2.3 The photon gas and radiative transfer 44 2.4 Electron-scattering opacity 47 2.5 Convective energy transport 50 2.6 Hydrogen and helium burning 52 2.7 The structures of main-sequence stars 54 2.8 Polytropes 57 2.9 Numerical solutions of the equations of stellar interiors 59 3 Statistical physics 63 3.1 The Maxwell-Boltzmann distribution 63 3.2 Quantum statistics 66 The Schrodinger equation The Dirac equation Photon quantum states Particle distribution functions
viii Contents 3.3 Thermodynamic functions of atomic and fermion gases 77 Nondegenerate, ionized gases Atomic gases Weak degeneracy Strong degeneracy 3.4 Ionization equilibrium 88 3.5 Molecules 90 3.6 Reaction equilibrium 98 3.7 Imperfect gases 103 3.8 The Boltzmann equation and transport coefficients in a gas 107 Electrical conductivity of a nondegenerate, ionized gas Thermal conductivity of a nondegenerate, ionized gas Viscosity of a nondegenerate, ionized gas Thermal conduction in a degenerate electron gas 4 Absorption processes 724 4.1 Time-independent solutions of the Schrodinger equation 724 4.2 Line widths caused by spontaneous emission 727 4.3 Einstein coefficients of absorption and emission 128 4.4 Time-dependent perturbation theory 131 4.5 Calculation of absorption cross sections and radiative lifetimes 140 The classical oscillator 4.6 Bound-free absorption 747 4.7 Free-free absorption 757 4.8 Stellar opacities 758 5 Stellar atmospheres, convective envelopes and stellar winds 161 5.1 Radiative transfer in stellar atmospheres 767 5.2 The Eddington approximation 162 5.3 Line broadening by the Doppler effect 765 5.4 The Voigt line profile 767 5.5 The equation of radiative transfer for spectral-line radiation 769 5.6 Convective envelopes 772 Nonadiabatic mixing-length theory 5.7 Stellar winds 180 5.8 Molecular-line emission from stellar winds 183
Contents ix 6 Thermonuclear reactions and nucleosynthesis 792 6.1 Nonresonant thermonuclear reactions 792 6.2 The penetration factor 198 The WKB approximation Barrier penetration in parabolic coordinates 6.3 Scattering and resonant reactions 206 6.4 Nuclear energy levels 272 6.5 Helium burning 224 6.6 Nucleosynthesis during hydrogen-burning stages 225 6.7 Carbon, oxygen and silicon burning 227 6.8 Neutron-capture nucleosynthesis 229 7 Weak interactions in stellar interiors 236 7.1 Introduction 236 7.2 Solar neutrinos 237 7.3 Neutrino emission and stellar evolution 240 7.4 Weak interactions in presupernova stars, supernovae and neutron stars 242 7.5 Weak-interaction decay rates and cross sections 246 The p-p reaction 7.6 Neutrino mass and solar neutrinos 256 8 Stellar stability and hydrodynamics 260 8.1 Pulsational instability 260 The equation of radial oscillation The condition for pulsational instability 8.2 Evolution to the red-giant branch and thermonuclear runaways 267 Thermonuclear runaways 8.3 Nonradial oscillations 272 8.4 Stellar hydrodynamics 274 8.5 Helioseismology and stellar seismology 277 9 Binary stars, mass accretion, stellar rotation and meridional circulation 280 9.1 Binary stars 280 9.2 Mass accretion 285 Spherical mass accretion Mass accretion from a stellar wind Accretion disks 9.3 Stellar rotation 293
x Contents 9.4 Meridional circulation 296 10 Stellar magnetic fields 302 10.1 Magnetic fields in stellar winds 302 10.2 Hydrostatic equilibrium in the presence of strong magnetic fields 306 10.3 Magnetohydrodynamic waves 309 10.4 Dynamo magnetic fields 313 10.5 Pulsar magnetic fields 317 11 White dwarfs, novae and supernovae 325 11.1 White dwarfs 325 Cooling of white dwarfs Crystallization and heat capacity of the ionic lattice Coulomb corrections to the equation of state 11.2 Novae 335 11.3 Supernovae 339 Explosive carbon-burning supernovae Gravitational collapse supernovae Further comments on supernovae 12 General relativity 359 12.1 Tensor analysis 359 12.2 Riemannian geometry 360 12.3 The Einstein equations 366 12 A The spherically symmetric gravitational field 369 Deflection of electromagnetic waves Advance of periastron 12.5 Gravitational radiation 375 13 Neutron stars and black holes 385 13.1 Neutron stars 385 Hydrostatic equilibrium from the Einstein equations Hydrostatic equilibrium from a variational principle Interaction between neutrons Superfluidity and superconductivity in neutron stars 13.2 Black holes 398 Spherical black holes Rotating black holes
Contents xi 13.3 Compact x-ray sources 405 X-ray pulsars X-ray bursters Cygnus X-l SS433 13.4 Accretion onto neutron stars and white dwarfs 475 13.5 Accretion disks surrounding black holes 418 The Kompaneets equation 13.6 X-ray pulsar spin-up 427 Appendix 1 Physical and astronomical constants 434 Appendix 2 Further comments on the Dirac equation 435 Appendix 3 Mathematical appendix 438 Appendix 4 Polytropes and the isothermal gas sphere 447 Appendix 5 Solutions to selected problems 451 References 472 Index 479
Preface Remarkable progress in understanding stellar phenomena has occurred in recent decades. This textbook discusses in some detail those equations and physical processes that are of greatest relevance to stellar interiors and atmospheres and closely related astrophysics. Motivation for writing this book came from my own research interests and also from teaching graduate astrophysics courses, especially a course on stellar interiors at the University of Maryland. Although the text emphasizes physical principles, astronomical results and unresolved issues are also described. Introductory material on the history of stellar astrophysics, astronomical observations, star formation and stellar evolution are given in Chapter 1, which also contains a discussion of spectroscopic binaries. Differences between single and binary star evolution have explained a number of interesting observations that are described further in later chapters. Stellar interiors is one of the most fundamental subjects in astrophysics. Although complicated physical processes are decisive in explaining some predictions of stellar model calculations, the basic principles of stellar interiors do not require a comprehensive knowledge of them. Chapter 2 gives an introductory discussion of the physics and equations of stellar interiors. It also includes a short description of numerical methods. Statistical physics provides the theoretical basis for much of stellar astrophysics. In Chapter 3 those aspects of statistical physics that are of greatest relevance are developed in some detail. Stellar opacities play a vital role in interpreting observations. Absorption processes are described in Chapter 4. This latter chapter includes self-contained discussions of bound-bound absorption by hydrogenic ions, bound-free absorption and free-free absorption. The basic principles of stellar atmospheres and a discussion of stellar winds are presented in Chapter 5. Thermonuclear reactions generate most of the energy that is radiated from the photospheres of stars. They also synthesize most elements. Much of the research effort in stellar atmospheres and interiors is motivated by determining abundances and providing theoretical explanations for observations. Chapter 6 discusses low-energy nuclear reactions, some important concepts of nuclear phy&ics and nucleosynthesis. Weak interactions are described in Chapter 7. Although most stars are in hydrostatic equilibrium, important classes of stars such as Cepheids, RR Lyrae variables and long-period variables are unstable to radial pulsations, whereas some other stars are unstable to nonradial oscillations. Asymptotic-giant-branch
xiv Preface stars become thermally unstable. Type II supernovae are caused by dynamical core collapse. Chapter 8 discusses the theory of stellar instabilities and gives a brief description of spherical hydrodynamics. By definition close binary systems are binary stars in which mass transfer between the two components becomes important. Chapter 9 contains discussions of binary stars and mass accretion. Stellar rotation and the related phenomenon of meridional circulation are also included. Several topics related to stellar magneticfieldsare described in Chapter 10. The end states of stellar evolution are white dwarfs, neutron stars and black holes. White dwarfs, classical novae and supernovae are discussed in Chapter 11. The occurrence of supernovae is closely connected to the Chandrasekhar limit, which is the upper limit to the mass of a white dwarf. General relativity is essential in any treatment of neutron stars and black holes. Chapter 12 contains a concise introduction to general relativity, whereas most of Chapter 13 is concerned with neutron stars and black holes. This latter chapter emphasizes observations as well as theory. X-ray astronomy has played a particularly important role in the development of neutron-star and black hole astrophysics. The writing of this book was substantially influenced by teaching graduate-level courses and participating on various research efforts. I am very grateful to students who took my stellar astrophysics courses and research collaborators. I also wish to thank J. Hall, S. Lehr and S. Smith for performing the difficult task of typing the manuscript.